Description
These days, advanced multiscale hybrid materials are being produced in the industry, studied by universities, and used in several applications. Unlike for macromaterials, it is difficult to obtain the physical, mechanical, electrical, and thermal properties of nanomaterials because of the scale. Designers, however, must have knowledge of these properties to perform any finite element analysis or durability and damage tolerance analysis. This is the book that brings this knowledge within easy reach.
What makes the book unique is the fact that its approach that combines multiscale multiphysics and statistical analysis with multiscale progressive failure analysis. The combination gives a very powerful tool for minimizing tests, improving accuracy, and understanding the effect of the statistical nature of materials, in addition to the mechanics of advanced multiscale materials, all the way to failure. The book focuses on obtaining valid mechanical properties of nanocomposite materials by accurate prediction and observed physical tests, as well as by evaluation of test anomalies of advanced multiscale nanocomposites containing nanoparticles of different shapes, such as chopped fiber, spherical, and platelet, in polymeric, ceramic, and metallic materials. The prediction capability covers delamination, fracture toughness, impact resistance, conductivity, and fire resistance of nanocomposites. The methodology employs a high-fidelity procedure backed with comparison of predictions with test data for various types of static, fatigue, dynamic, and crack growth problems. Using the proposed approach, a good correlation between the simulation and experimental data is established.
Table of Contents
Nanostructure Bulk Property Predictions Using Molecular Mechanics
Jerry Housner and Frank Abdi
Obtaining Material Properties from the Bottom-Up Approach
B. Farahmand
Fiber–Matrix Interphase Effects on Damage Progression in Composite Structures
Levon Minnetyan, Xiaofeng Su, and Frank Abdi
Composite Nanomechanics: A Mechanistic Properties Prediction
Christos C. Chamis
Analyzing Interlaminar Shear Strength of Multiscale Composites via Combined Finite Element and Progressive Failure Analysis Approach
Mohit Garg, Frank Abdi, and Stuart McHugh
Validation for Multiscale Composites: Glass/Epoxy/Silica Nanoparticles
Mohit Garg and Parviz Yavari
Influence of Nanoparticles and Effect of Defects on Mode I and II Fracture Toughness and Impact Resistance
Christos C. Chamis, Frank Abdi, Harsh Baid, and Parviz Yavari
Prediction/Verification of Composite Electrical Properties and Nano-Insertion Improvement
Levon Minnetyan, Frank Abdi, Christos C. Chamis, and Dade Huang
Polymer Nanocomposites as Ablative Materials: A Comprehensive Review
J. H. Koo, M. Natali, J. Tate, and E. Allcorn
Antifriction Nanocomposites Based on the Chemically Modified Ultra-High Molecular Weight Polyethylene
Lyudmila A. Kornienko and Sergey V. Panin
Modeling of Mechanical Properties in Nanoparticle Reinforced Polymers Using Atomistic Simulations
Samit Roy and Avinash Reddy Akepati
Prediction of Effect of Waviness, Interfacial Bonding, and Agglomeration of Carbon Nanotubes on Their Polymer Composites
Mohit Garg, Frank Abdi, and Jerrold Housner
Dispersion of Nanoparticles in Polymers
Ambrose C. Taylor and David J. Bray
Modeling of the Mechanical Properties of Nanoparticle/Polymer Composites
G. M. Odegard, T. C. Clancy, and T. S. Gates
Predicting the Elastic Properties of CNF/Thermoset Polymer Composites Considering the Effect of Interphase and Fiber Waviness
Masoud Rais-Rohani and Mohammad Rouhi
Part 1: Multiscale Nanocomposite Fatigue Life Determination
Kamran Nikbin and Anthony J. Kinloch
Part 2: Multiscale Nanocomposite Fatigue Life Determination
Kamran Nikbin and Anthony J. Kinloch
Stress Analysis and Fracture in Nanolaminate Composites
Christos C. Chamis
Probabilistic Simulation for Nanocomposite Fracture
Christos C. Chamis
Material Characterization and Microstructural Assessment: Fatigue Curve S-N Development Using Fracture Mechanics
Hamid Saghizadeh